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THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS ''AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ***********************************************************************/ /********************************************************************** * Correlation Matrix Computations for LS estimate. **********************************************************************/ #include "SKP_Silk_main_FIX.h" /* Calculates correlation vector X'*t */ void SKP_Silk_corrVector_FIX( const SKP_int16 *x, /* I x vector [L + order - 1] used to form data matrix X */ const SKP_int16 *t, /* I target vector [L] */ const SKP_int L, /* I Length of vectors */ const SKP_int order, /* I Max lag for correlation */ SKP_int32 *Xt, /* O Pointer to X'*t correlation vector [order] */ const SKP_int rshifts /* I Right shifts of correlations */ ) { SKP_int lag, i; const SKP_int16 *ptr1, *ptr2; SKP_int32 inner_prod; ptr1 = &x[ order - 1 ]; /* Points to first sample of column 0 of X: X[:,0] */ ptr2 = t; /* Calculate X'*t */ if( rshifts > 0 ) { /* Right shifting used */ for( lag = 0; lag < order; lag++ ) { inner_prod = 0; for( i = 0; i < L; i++ ) { inner_prod += SKP_RSHIFT32( SKP_SMULBB( ptr1[ i ], ptr2[i] ), rshifts ); } Xt[ lag ] = inner_prod; /* X[:,lag]'*t */ ptr1--; /* Go to next column of X */ } } else { SKP_assert( rshifts == 0 ); for( lag = 0; lag < order; lag++ ) { Xt[ lag ] = SKP_Silk_inner_prod_aligned( ptr1, ptr2, L ); /* X[:,lag]'*t */ ptr1--; /* Go to next column of X */ } } } /* Calculates correlation matrix X'*X */ void SKP_Silk_corrMatrix_FIX( const SKP_int16 *x, /* I x vector [L + order - 1] used to form data matrix X */ const SKP_int L, /* I Length of vectors */ const SKP_int order, /* I Max lag for correlation */ const SKP_int head_room, /* I Desired headroom */ SKP_int32 *XX, /* O Pointer to X'*X correlation matrix [ order x order ]*/ SKP_int *rshifts /* I/O Right shifts of correlations */ ) { SKP_int i, j, lag, rshifts_local, head_room_rshifts; SKP_int32 energy; const SKP_int16 *ptr1, *ptr2; /* Calculate energy to find shift used to fit in 32 bits */ SKP_Silk_sum_sqr_shift( &energy, &rshifts_local, x, L + order - 1 ); /* Add shifts to get the desired head room */ head_room_rshifts = SKP_max( head_room - SKP_Silk_CLZ32( energy ), 0 ); energy = SKP_RSHIFT32( energy, head_room_rshifts ); rshifts_local += head_room_rshifts; /* Calculate energy of first column (0) of X: X[:,0]'*X[:,0] */ /* Remove contribution of first order - 1 samples */ for( i = 0; i < order - 1; i++ ) { energy -= SKP_RSHIFT32( SKP_SMULBB( x[ i ], x[ i ] ), rshifts_local ); } if( rshifts_local < *rshifts ) { /* Adjust energy */ energy = SKP_RSHIFT32( energy, *rshifts - rshifts_local ); rshifts_local = *rshifts; } /* Calculate energy of remaining columns of X: X[:,j]'*X[:,j] */ /* Fill out the diagonal of the correlation matrix */ matrix_ptr( XX, 0, 0, order ) = energy; ptr1 = &x[ order - 1 ]; /* First sample of column 0 of X */ for( j = 1; j < order; j++ ) { energy = SKP_SUB32( energy, SKP_RSHIFT32( SKP_SMULBB( ptr1[ L - j ], ptr1[ L - j ] ), rshifts_local ) ); energy = SKP_ADD32( energy, SKP_RSHIFT32( SKP_SMULBB( ptr1[ -j ], ptr1[ -j ] ), rshifts_local ) ); matrix_ptr( XX, j, j, order ) = energy; } ptr2 = &x[ order - 2 ]; /* First sample of column 1 of X */ /* Calculate the remaining elements of the correlation matrix */ if( rshifts_local > 0 ) { /* Right shifting used */ for( lag = 1; lag < order; lag++ ) { /* Inner product of column 0 and column lag: X[:,0]'*X[:,lag] */ energy = 0; for( i = 0; i < L; i++ ) { energy += SKP_RSHIFT32( SKP_SMULBB( ptr1[ i ], ptr2[i] ), rshifts_local ); } /* Calculate remaining off diagonal: X[:,j]'*X[:,j + lag] */ matrix_ptr( XX, lag, 0, order ) = energy; matrix_ptr( XX, 0, lag, order ) = energy; for( j = 1; j < ( order - lag ); j++ ) { energy = SKP_SUB32( energy, SKP_RSHIFT32( SKP_SMULBB( ptr1[ L - j ], ptr2[ L - j ] ), rshifts_local ) ); energy = SKP_ADD32( energy, SKP_RSHIFT32( SKP_SMULBB( ptr1[ -j ], ptr2[ -j ] ), rshifts_local ) ); matrix_ptr( XX, lag + j, j, order ) = energy; matrix_ptr( XX, j, lag + j, order ) = energy; } ptr2--; /* Update pointer to first sample of next column (lag) in X */ } } else { for( lag = 1; lag < order; lag++ ) { /* Inner product of column 0 and column lag: X[:,0]'*X[:,lag] */ energy = SKP_Silk_inner_prod_aligned( ptr1, ptr2, L ); matrix_ptr( XX, lag, 0, order ) = energy; matrix_ptr( XX, 0, lag, order ) = energy; /* Calculate remaining off diagonal: X[:,j]'*X[:,j + lag] */ for( j = 1; j < ( order - lag ); j++ ) { energy = SKP_SUB32( energy, SKP_SMULBB( ptr1[ L - j ], ptr2[ L - j ] ) ); energy = SKP_SMLABB( energy, ptr1[ -j ], ptr2[ -j ] ); matrix_ptr( XX, lag + j, j, order ) = energy; matrix_ptr( XX, j, lag + j, order ) = energy; } ptr2--;/* Update pointer to first sample of next column (lag) in X */ } } *rshifts = rshifts_local; }